Paper Titles
Thermomechanical Modelling and Shape Prediction in 4D Printing Using FEA
p.287
Advanced FE Modeling for Predicting Component Properties in Additive Manufacturing
p.299
Measurement of Forces Generated during Robotized Additive Manufacturing Process Using Pellet Extruder
p.313
Anisotropy and Stress-State-Dependent Fracture in Additively Manufactured Metals
p.325
Effect of Preheating Temperature on the Optimal Processing Windows of Inconel 718 Processed by Laser Power Bed Fusion
p.333
Effects of Current Density during Electrically Assisted Friction Stir Additive Manufacturing Hole Repair of AA 7075 on a Conventional Machine
p.347
Comparison between 2D and 3D Thermal Finite Element Models of Directed Energy Deposition
p.359
Additive Manufacturing of Automotive Metal Multi-Material Shunt Resistor: Cost and Carbon Footprint Analysis
p.373
Resistance to Fracture of Additively Manufactured Aluminium Alloy AlSi10Mg under Plane Stress Conditions
p.383

Effect of Preheating Temperature on the Optimal Processing Windows of Inconel 718 Processed by Laser Power Bed Fusion

Article Preview
View Pdf By email

Abstract:

Laser Powder Bed Fusion (LPBF) of Inconel 718 (IN718) enables near-net-shape fabrication of complex components but is limited by narrow processing windows, crack susceptibility, and defect formation. In this work, the influence of substrate preheating on LPBF processability, densification, microstructure, and hardness of IN718 is investigated. Cuboid samples (10 × 10 × 10 mm³) were fabricated at three preheating temperatures (80 °C, 300 °C, and 500 °C), while laser power was varied between 100 W and 200 W with fixed layer thickness (30 µm) and hatch spacing (80 µm). Density was assessed using helium pycnometry and optical microscopy, while both optical and scanning electron microscopy (SEM) were used to characterize melt pool (MP) geometry, cellular substructure, cracking behavior, and oxide inclusions. Vickers hardness (HV10) measurements were performed to assess as-built mechanical response under high load of 10kg, whereas micro hardness under a load of 0.3kg was used to evaluate the hardening and/or softening phenomena occurring during LPBF processing. The results show that increasing preheating temperature significantly widens the full-density processing window, suppresses cracking, stabilizes MPs, and promotes partial in-situ ageing, leading to enhanced as-built hardness. Nevertheless, to high preheating temperatures appear to promote both the occurrence of large porosities and the formation of oxides inclusions. These findings highlight the need for preheating-aware LPBF process metrics beyond classical volumetric energy density.

You might also be interested in these eBooks
Additive Manufacturing View Preview

Info:

Periodical:

Key Engineering Materials (Volume 1047)

Pages:

333-345

Online since:

April 2026

Authors:

Jérôme Tchoufang Tchuindjang*, Edoardo Fassinato, Olivier Dedry, Anne Mertens

Keywords:

Inconel 718, Laser Powder Bed Fusion, Preheating Temperature, Processing Windows

Export:

RIS, BibTeX

Permissions:

Creative Commons CC BY 4.0

Share:

* - Corresponding Author

References

[1] Satyanarayana, D. V. V., and Eswara Prasad, N. "Nickel-Based Superalloys." In: Prasad, N. E., Wanhill, R. J. H., eds. Aerospace Materials and Material Technologies : Volume 1: Aerospace Materials. Singapore, Springer, 2017. p.199–228.

DOI: 10.1007/978-981-10-2134-3_9

Google Scholar

[2] Bian, Z., Li, M., Liu, H., et al. "Comprehensive Optimization of Tensile and Creep Properties of Inconel 718 Superalloy at Room Temperature and Elevated Temperature Through Grain Boundary Engineering Treatments," 2024.

DOI: 10.2139/ssrn.4916263

Google Scholar

[3] Bryndza, G., Tchuindjang, J. T., Chen, F., et al. "Review of the Microstructural Impact on Creep Mechanisms and Performance for Laser Powder Bed Fusion Inconel 718," Materials, V. 18, No. 2, 2025, p.276.

DOI: 10.3390/ma18020276

Google Scholar

[4] Darolia, R. "Development of strong, oxidation and corrosion resistant nickel-based superalloys: critical review of challenges, progress and prospects," International Materials Reviews, V. 64, No. 6, 2019, p.355–80.

DOI: 10.1080/09506608.2018.1516713

Google Scholar

[5] Radavich, J. F., and Carneiro, T. "A microstructural study of alloy 718 Plus," Superalloys, V. 718, 2005, p.625–706.

DOI: 10.7449/2005/superalloys_2005_329_340

Google Scholar

[6] Ajay, P., and Dabhade, V. V. "Heat treatments of Inconel 718 nickel-based superalloy: A Review," Metals and Materials International, V. 31, No. 5, 2025, p.1204–31.

DOI: 10.1007/s12540-024-01812-8

Google Scholar

[7] Yang, S., Tang, Y., and Zhao, Y. F. "A new part consolidation method to embrace the design freedom of additive manufacturing," Journal of Manufacturing Processes, V. 20, 2015, p.444–9.

DOI: 10.1016/j.jmapro.2015.06.024

Google Scholar

[8] DebRoy, T., Wei, H. L., Zuback, J. S., et al. "Additive manufacturing of metallic components – Process, structure and properties," Progress in Materials Science, V. 92, 2018, p.112–224.

DOI: 10.1016/j.pmatsci.2017.10.001

Google Scholar

[9] Schmelzle, J., Kline, E. V., Dickman, C. J., et al. "(Re)Designing for Part Consolidation: Understanding the Challenges of Metal Additive Manufacturing," Journal of Mechanical Design, V. 137, No. 111404, 2015.

DOI: 10.1115/1.4031156

Google Scholar

[10] Liu, M., Kumar, A., Bukkapatnam, S., et al. "A review of the anomalies in directed energy deposition (DED) processes & potential solutions-part quality & defects," Procedia Manufacturing, V. 53, 2021, p.507–18.

DOI: 10.1016/j.promfg.2021.06.093

Google Scholar

[11] Herzog, D., Seyda, V., Wycisk, E., et al. "Additive manufacturing of metals," Acta Materialia, V. 117, 2016, p.371–92.

DOI: 10.1016/j.actamat.2016.07.019

Google Scholar

[12] Saboori, A., Aversa, A., Marchese, G., et al. "Application of directed energy deposition-based additive manufacturing in repair," Applied Sciences, V. 9, No. 16, 2019, p.3316.

DOI: 10.3390/app9163316

Google Scholar

[13] Lehmann, T., Rose, D., Ranjbar, E., et al. "Large-scale metal additive manufacturing: a holistic review of the state of the art and challenges," International Materials Reviews, V. 67, No. 4, 2022, p.410–59.

DOI: 10.1080/09506608.2021.1971427

Google Scholar

[14] Li, M., Du, W., Elwany, A., et al. "Metal Binder Jetting Additive Manufacturing: A Literature Review," Journal of Manufacturing Science and Engineering, V. 142, No. 090801, 2020.

DOI: 10.1115/1.4047430

Google Scholar

[15] Jiang, C.-P., Masrurotin., Wibisono, A. T., et al. "Enhancing internal cooling channel design in Inconel 718 turbine blades via laser powder bed fusion: a comprehensive review of surface topography enhancements," International Journal of Precision Engineering and Manufacturing, V. 26, No. 2, 2025, p.487–511.

DOI: 10.1007/s12541-024-01177-3

Google Scholar

[16] Cobbinah, P. V., Nzeukou, R. A., Onawale, O. T., et al. "Laser powder bed fusion of potential superalloys: a review," Metals, V. 11, No. 1, 2020, p.58.

DOI: 10.3390/met11010058

Google Scholar

[17] Wu, H., Zhou, J., Huang, L., et al. "Advances in Crack Formation Mechanisms, Evaluation Models, and Compositional Strategies for Additively Manufactured Nickel-Based Superalloys," Computer Modeling in Engineering & Sciences, V. 143, No. 3, 2025, p.2675.

DOI: 10.32604/cmes.2025.064854

Google Scholar

[18] Jeong, S. G., Ahn, S. Y., Kim, E. S., et al. "Liquation cracking in laser powder bed fusion-fabricated Inconel718 of as-built, stress-relieved, and hot isostatic pressed conditions," Materials Science and Engineering: A, V. 888, 2023, p.145797.

DOI: 10.1016/j.msea.2023.145797

Google Scholar

[19] Zhang, Y., Yang, L., Chen, T., et al. "Sensitivity of liquation cracking to deposition parameters and residual stresses in laser deposited IN718 alloy," Journal of Materials Engineering and performance, V. 26, No. 11, 2017, p.5519–29.

DOI: 10.1007/s11665-017-2966-2

Google Scholar

[20] Li, Y., Long, H., Wang, Y., et al. "A novel and high-efficiency dual-electron gun concurrent preheating additive manufacturing technology: suppressing thermal cracks in non-weldable IN738LC nickel-based superalloy by mitigating temperature fluctuations," Virtual and Physical Prototyping, V. 20, No. 1, 2025, p. e2518615.

DOI: 10.1080/17452759.2025.2518615

Google Scholar

[21] Fu, Z., and Körner, C. "Actual state-of-the-art of electron beam powder bed fusion," European Journal of Materials, V. 2, No. 1, 2022, p.54–116.

DOI: 10.1080/26889277.2022.2040342

Google Scholar

[22] Yue, T., Zou, Z., Zhang, S., et al. "Effects of volumetric energy density on melting modes, printability, microstructures, and mechanical properties of laser powder bed fusion (L-PBF) printed pure nickel," Materials Science and Engineering: A, V. 909, 2024, p.146871.

DOI: 10.1016/j.msea.2024.146871

Google Scholar

[23] Pramod, S., and Kesavan, D. "Melting modes of laser powder bed fusion (L-PBF) processed IN718 alloy: Prediction and experimental analysis," Advances in Industrial and Manufacturing Engineering, V. 6, 2023, p.100106.

DOI: 10.1016/j.aime.2022.100106

Google Scholar

[24] Hu, Y., Jia, H.-B., Hu, Y.-Q., et al. "Thermal cycling on microstructure and mechanical properties of laser powder bed fusion manufactured IN738LC alloy," Rare Metals, V. 43, No. 12, 2024, p.6649–72.

DOI: 10.1007/s12598-024-02851-1

Google Scholar

[25] Haribaskar, R., and Kumar, T. S. "Defects in metal additive manufacturing: formation, process parameters, postprocessing, challenges, economic aspects, and future research directions," 3D Printing and Additive Manufacturing, V. 11, No. 4, 2024, pp. e1629–55.

DOI: 10.1089/3dp.2022.0344

Google Scholar

[26] Guo, L., Liu, H., Wang, H., et al. "Identifying the keyhole stability and pore formation mechanisms in laser powder bed fusion additive manufacturing," Journal of Materials Processing Technology, V. 321, 2023, p.118153.

DOI: 10.1016/j.jmatprotec.2023.118153

Google Scholar

[27] Huang, Y., Fleming, T. G., Clark, S. J., et al. "Keyhole fluctuation and pore formation mechanisms during laser powder bed fusion additive manufacturing," Nature communications, V. 13, No. 1, 2022, p.1170.

DOI: 10.1038/s41467-022-28694-x

Google Scholar

[28] Pant, P., Salvemini, F., Proper, S., et al. "A study of the influence of novel scan strategies on residual stress and microstructure of L-shaped LPBF IN718 samples," Materials & design, V. 214, 2022, p.110386.

DOI: 10.1016/j.matdes.2022.110386

Google Scholar

[29] Liu, L., Wang, D., Yang, Y., et al. "Effect of scanning strategies on the microstructure and mechanical properties of inconel 718 alloy fabricated by laser powder bed fusion," Advanced Engineering Materials, V. 25, No. 5, 2023, p.2200492.

DOI: 10.1002/adem.202200492

Google Scholar

[30] Gruber, K., Smolina, I., Kasprowicz, M., et al. "Evaluation of Inconel 718 metallic powder to optimize the reuse of powder and to improve the performance and sustainability of the laser powder bed fusion (LPBF) process," Materials, V. 14, No. 6, 2021, p.1538.

DOI: 10.3390/ma14061538

Google Scholar

[31] Newell, D. J., O'Hara, R. P., Cobb, G. R., et al. "Mitigation of scan strategy effects and material anisotropy through supersolvus annealing in LPBF IN718," Materials Science and Engineering: A, V. 764, 2019, p.138230.

DOI: 10.1016/j.msea.2019.138230

Google Scholar

[32] Caiazzo, F., Alfieri, V., and Casalino, G. "On the relevance of volumetric energy density in the investigation of Inconel 718 laser powder bed fusion," Materials, V. 13, No. 3, 2020, p.538.

DOI: 10.3390/ma13030538

Google Scholar

[33] de Leon Nope, G. V., Perez-Andrade, L. I., Corona-Castuera, J., et al. "Study of volumetric energy density limitations on the IN718 mesostructure and microstructure in laser powder bed fusion process," Journal of Manufacturing Processes, V. 64, 2021, p.1261–72.

DOI: 10.1016/j.jmapro.2021.02.043

Google Scholar

[34] Kakehi, K., Chowdhury, H. T., Shinoda, Y., et al. "Effects of base plate temperature on microstructure evolution and high-temperature mechanical properties of IN718 processed by laser powder bed fusion using simulation and experiment," The International Journal of Advanced Manufacturing Technology, V. 130, No. 11, 2024, p.5777–93.

DOI: 10.1007/s00170-024-13028-6

Google Scholar

[35] Shrivastava, A., Kumar, S. A., Rao, S., et al. "Exploring How LPBF process parameters impact the interface characteristics of LPBF Inconel 718 deposited on Inconel 718 wrought substrates," Optics & Laser Technology, V. 174, 2024, p.110571.

DOI: 10.1016/j.optlastec.2024.110571

Google Scholar

[36] Ur Rehman, A., Pitir, F., and Salamci, M. U. "Laser powder bed fusion (LPBF) of In718 and the impact of pre-heating at 500 and 1000° C: Operando Study," Materials, V. 14, No. 21, 2021, p.6683.

DOI: 10.3390/ma14216683

Google Scholar

[37] Baldi, N., Giorgetti, A., Palladino, M., et al. "Study on the Effect of Preheating Temperatures on Melt Pool Stability in Inconel 718 Components Processed by Laser Powder Bed Fusion," Metals, V. 13, No. 10, 2023, p.1792.

DOI: 10.3390/met13101792

Google Scholar

[38] Zielinski, J., Theunissen, J., Kruse, H., et al. "Understanding Inhomogeneous Mechanical Properties in PBF-LB/M Manufactured Parts Due to Inhomogeneous Macro Temperature Profiles Based on Process-Inherent Preheating," Journal of Manufacturing and Materials Processing, V. 7, No. 3, 2023, p.88.

DOI: 10.3390/jmmp7030088

Google Scholar

[39] Chen, Y., Wang, W., Ou, Y., et al. "Effect of high preheating on the microstructure and mechanical properties of high gamma prime Ni-based superalloy manufactured by laser powder bed fusion," Journal of Alloys and Compounds, V. 960, 2023, p.170598.

DOI: 10.1016/j.jallcom.2023.170598

Google Scholar

[40] Ur Rehman, A., Pitir, F., and Salamci, M. U. "Laser Powder Bed Fusion (LPBF) of In718 and the Impact of Pre-Heating at 500 and 1000 °C: Operando Study," Materials, V. 14, No. 21, 2021, p.6683.

DOI: 10.3390/ma14216683

Google Scholar

[41] Wang, X., and Chou, K. "Effects of thermal cycles on the microstructure evolution of Inconel 718 during selective laser melting process," Additive Manufacturing, V. 18, 2017, p.1–14.

DOI: 10.1016/j.addma.2017.08.016

Google Scholar

[42] Zhang, H., Wu, Y., Wang, Y., et al. "In-situ nanoscale precipitation behavior and strengthening mechanism of WC/IN718 composites manufactured by laser powder bed fusion," Composites Part B: Engineering, V. 284, 2024, p.111727.

DOI: 10.1016/j.compositesb.2024.111727

Google Scholar

[43] Tucho, W. M., Cuvillier, P., Sjolyst-Kverneland, A., et al. "Microstructure and hardness studies of Inconel 718 manufactured by selective laser melting before and after solution heat treatment," Materials Science and Engineering: A, V. 689, 2017, p.220–32.

DOI: 10.1016/j.msea.2017.02.062

Google Scholar

[44] Kumara, C., Balachandramurthi, A. R., Goel, S., et al. "Toward a better understanding of phase transformations in additive manufacturing of Alloy 718," Materialia, V. 13, 2020, p.100862.

DOI: 10.1016/j.mtla.2020.100862

Google Scholar

[45] Simonelli, M., Tuck, C., Aboulkhair, N. T., et al. "A Study on the Laser Spatter and the Oxidation Reactions During Selective Laser Melting of 316L Stainless Steel, Al-Si10-Mg, and Ti-6Al-4V," Metallurgical and Materials Transactions A, V. 46, No. 9, 2015, p.3842–51.

DOI: 10.1007/s11661-015-2882-8

Google Scholar

[46] Beyhaghi, M., Rouhani, M., Hobley, J., et al. "In-situ and ex-situ comparison of oxidation of Inconel 718 manufactured by selective laser melting and conventional methods up to 650 °C," Applied Surface Science, V. 569, 2021, p.151037.

DOI: 10.1016/j.apsusc.2021.151037

Google Scholar

[47] Ohtsuki, T., and Pistorius, P. C. "Oxide Behavior During Laser Surface Melting," Metals, V. 15, No. 6, 2025, p.627.

DOI: 10.3390/met15060627

Google Scholar

[48] Bryndza, G., Tchuindjang, J. T., Chen, F., et al. "Review of the Microstructural Impact on Creep Mechanisms and Performance for Laser Powder Bed Fusion Inconel 718," Materials, V. 18, No. 2, 2025, p.276.

DOI: 10.3390/ma18020276

Google Scholar

[49] Chaudhari, S. B., and Wakchaure, V. D. "A Comprehensive Review on the High-Temperature Behavior of Additively Manufactured Inconel 718." International Conference on Additive Manufacturing. Springer, 2024. p.439–524.

DOI: 10.1007/978-981-97-6016-9_34

Google Scholar

[50] Markanday, J. F. S. "Applications of alloy design to cracking resistance of additively manufactured Ni-based alloys," Materials Science and Technology, V. 38, No. 16, 2022, p.1300–14.

DOI: 10.1080/02670836.2022.2068759

Google Scholar

[51] Ghoussoub, J. N., Tang, Y. T., Dick-Cleland, W. J. B., et al. "On the Influence of Alloy Composition on the Additive Manufacturability of Ni-Based Superalloys," Metallurgical and Materials Transactions A, V. 53, No. 3, 2022, p.962–83.

DOI: 10.1007/s11661-021-06568-z

Google Scholar

[52] Chen, Q., Zhao, Y., Strayer, S., et al. "Elucidating the effect of preheating temperature on melt pool morphology variation in Inconel 718 laser powder bed fusion via simulation and experiment," Additive Manufacturing, V. 37, 2021, p.101642.

DOI: 10.1016/j.addma.2020.101642

Google Scholar

[53] Pramod, S., and Kesavan, D. "Melting modes of laser powder bed fusion (L-PBF) processed IN718 alloy: Prediction and experimental analysis," Advances in Industrial and Manufacturing Engineering, V. 6, 2023, p.100106.

DOI: 10.1016/j.aime.2022.100106

Google Scholar

[54] Coen, V., Goossens, L., and Hooreweder, B. V. "Methodology and experimental validation of analytical melt pool models for laser powder bed fusion," Journal of Materials Processing Technology, V. 304, 2022, p.117547.

DOI: 10.1016/j.jmatprotec.2022.117547

Google Scholar

[55] Hasani, N., Dharmendra, C., Sanjari, M., et al. "Laser powder bed fused Inconel 718 in stress-relieved and solution heat-treated conditions," Materials Characterization, V. 181, 2021, p.111499.

DOI: 10.1016/j.matchar.2021.111499

Google Scholar

[56] Jiang, R., Mostafaei, A., Wu, Z., et al. "Effect of heat treatment on microstructural evolution and hardness homogeneity in laser powder bed fusion of alloy 718," Additive Manufacturing, V. 35, 2020, p.101282.

DOI: 10.1016/j.addma.2020.101282

Google Scholar